KR20040057608A - An apparatus and method for driving laser diode - Google Patents

Abstract

PURPOSE: A method of driving an LD(Laser Diode) for data recording of an optical disk and a method therefor are provided to record data by using an LD driving signal without overpower, thereby simply detecting/storing a variable value for generating the LD driving signal. CONSTITUTION: A microcomputer detects prestored variable values(S10). When a recording operation is requested(S20), a digital recording signal processor generates a main pulse and a sub pulse, respectively(S21), and outputs the generated pulses to an LD driver. The digital recording signal processor outputs the sub pulse more quickly than the main pulse(S22). The LD driver outputs an LD driving signal to an LD of an optical pickup(S23). The optical pickup records data on an optical disk(S24). If a recording operation is completed(S30), the procedure is finished.

Description

An apparatus and method for driving a laser diode for recording data on an optical disk

The present invention relates to a laser diode driving apparatus and method for data recording of an optical disc such that a recording pit of a desired size is formed at a desired time point without a predetermined delay time during a recording operation.

According to the Orange Book, a recording disc specification, a mode 1 (Orange 1) or a mode 2 (Orange 2) recording method is applied as a method of recording data on an optical disc (CD-R). 2 The recording method is described in detail as follows.

First, the mode 1 recording method is a recording method in which overpower is applied in consideration of the media characteristics of an optical disc. In general, when a LD (Laser Diode) of an optical pickup is driven during recording, the rising of a signal due to the characteristics of the LD Since a recording time of a desired size is not formed at a desired time due to a predetermined delay time during rising, the mode 1 recording method applies overpower at the time of recording power on. That is, since the LD driving signal as shown in FIG. 1 is applied to the LD of the optical pickup, the rising of the signal is performed quickly in the waveform of the actual driving signal, thereby solving the above problem.

However, the mode 1 recording method has the advantage that the rising of the signal is accelerated by the overpower by applying the overpower as described above, so that the initial formation of the recording feet is accurate and stable, while the LD driving having the overpower is performed. In order to generate a signal, a number of variables need to be set. In this case, the variables to be set include Td, Tf, Tw, VWDC1, Contains VWDC2.

Therefore, in order to apply the mode 1 recording method, the variable values corresponding to the recording feet 3T to 11T of each disc manufacturer (disk code) must be detected and stored in a memory, in particular Td, Tf, Tw, etc. Since the values are different for each disk manufacturer and each recording foot, there is a big problem in the amount of work and time required for variable value detection and memory storage.

On the other hand, in the mode 2 recording method, the recording signal is formed by applying the driving signal without the overpower, that is, the LD driving signal as shown in FIG. 4 to the LD of the optical pickup, and at this time, the VWDC2 value is not necessary. Only Td, Tf, VRDC, and VWDC1 need to be set.

However, the mode 2 recording method has a merit of less work and time than the mode 1 recording method. However, due to the characteristics of the LD, a predetermined delay time occurs during the rising of the signal, so that the initial formation of the recording feet is not accurately performed. The quality of the recording mark is deteriorated, and the deterioration of the quality of the recording mark is more severe in high-speed recording.

Accordingly, the present invention was created to solve the above problems, and generates LD drive signals by recording data using LD drive signals without overpower as in the conventional mode 2 recording method. This makes it easy to detect and store the variable value for the data. When performing the recording operation, as in the conventional mode 1 recording method, the recording feet of the desired size are formed accurately and stably at a desired time point without any delay time. It is an object of the present invention to provide a laser diode driving apparatus and method for recording data of an optical disc.

FIG. 1 shows an example of an LD drive signal according to a conventional mode 1 recording method and a recording form on an optical disc by the LD drive signal.

Fig. 2 shows an example of drive pulses PEO, LDH, PWO according to the conventional mode 1 recording method.

3 shows an example of the driving voltages VRDC, VWDC1, VWDC2 according to the conventional mode 1 recording method.

4 shows an example of an LD drive signal according to a conventional mode 2 recording method and a recording form on an optical disc by the LD drive signal.

FIG. 5 shows the configuration of a preferred embodiment of an optical disk apparatus in which a laser diode driving apparatus for recording data of an optical disk according to the present invention is implemented.

Fig. 6 shows the flow of a preferred embodiment of the laser diode driving method for data recording of an optical disc according to the present invention;

Fig. 7 shows an example of drive pulses PEO, LDH, PWO according to the recording method of the present invention.

8 shows an example of the drive voltages VRDC, VWDC1, VWDC2 according to the recording method of the present invention.

Fig. 9 shows an example of an LD drive signal and a recording form on an optical disc by the LD drive signal according to the recording method of the present invention.

Fig. 10 shows a comparison between a conventional mode 1 recording method, a mode 2 recording method, and a recording form on an optical disc according to the recording method of the present invention.

※ Explanation of code for main part of drawing

10: optical disc 20: optical pickup

30a: digital recording signal processor 30b: digital reproduction signal processor

40: R / F part 50: LD driver

60: servo unit 70: drive unit

80: Micom 81: Roman

A laser diode driving apparatus for recording data on an optical disc according to the present invention for achieving the above object comprises: optical pickup means for recording data on an optical disc; Optical driving means for outputting an LD driving signal for driving the laser diode (LD) of the optical pickup means to adjust the optical power of the optical pickup means; And control means for generating and outputting a main pulse for the driving signal and a sub pulse having a predetermined width, and outputting the sub pulse a predetermined time before the main pulse.

In addition, a laser diode driving method for recording data of an optical disk according to the present invention includes a first step of confirming a manufacturer and a recording value of a variable corresponding to each recording fit and a manufacturer of an inserted optical disk; A second step of generating and outputting a sub-pulse having a main pulse and a predetermined width based on the identified value, and outputting the sub-pulse a predetermined time before the main pulse; A third step of outputting a driving signal for driving an optical pickup internal laser diode from the main pulse and the subpulse; And a fourth step of recording data on the optical disc with the optical power controlled by the drive signal.

Best Mode for Carrying Out the Invention Preferred embodiments of the laser diode driving apparatus and method for data recording of an optical disc according to the present invention will now be described in detail with reference to the accompanying drawings.

FIG. 5 shows the configuration of a preferred embodiment of an optical disk apparatus in which a laser diode driving apparatus for recording data of an optical disk according to the present invention is implemented, and records data on the optical disk 10, An optical pickup 20 for detecting a recording signal from the recording surface; After converting the data into the recording format by adding an error correction code (ECC) or the like to the input digital data, the data converted into the recording format is reconverted into a bit stream, and the main pulse is output based on the bit stream. A digital recording signal processor 30a generating a sub pulse having a set pulse width and outputting the sub pulse with a predetermined time ahead of the main pulse; An R / F unit 40 for outputting driving voltages VDRC, VWDC1, and VWDC2, and for shaping the signal detected by the optical pickup 20 as a binary signal; LD driver 50 for outputting the LD driving signal from the driving pulse and the driving voltage input from the digital recording signal processor 30a and the R / F unit 40 to adjust the optical power of the optical pickup 20. ; A drive unit 70 for rotating the spindle motor M and the optical pickup 20; A servo unit 60 for controlling the driving of the drive unit 70 from the servo error signals F.E and T.E of the optical pickup 20 and the rotational speed of the optical disc 10; A digital reproduction signal processor (30b) for restoring the binary signal to original data with its clock synchronized with the binary signal; A ROM 81 in which variable values for applying an optimal write strategy are stored for each recording feet 3T to 11T for each disc manufacturer (by disc code); And a microcomputer 80 which performs a recording operation based on the variable value stored in the ROM 81.

In this case, the laser diode LD of the optical pickup 20 is operated by an LD driving signal (current value) of the LD driver 50, and the LD driver 50 is driven with driving voltages VDRC, VWDC1, and VWDC2. ) And the driving pulses (PWO, PEO, LDH) output the LD driving signal to the LD, which will be described in more detail below.

Next, each driving pulse and driving voltage used in the present invention will be described.

First, VRDC is a driving voltage required when reading data, VWDC1 is a main driving voltage required when writing data, and VWDC2 is such that initial formation of a recording pit is accurately and stably performed when data is written by VWDC1. This is a sub drive voltage corresponding to the overpower additionally given.

In addition, PWO is the driving pulse of the VRDC, PEO is used as the main pulse as the driving pulse of the VWDC1, and LDH is used as the sub pulse as the driving pulse of the VWDC2 which is overpower. Is given equal to the signal level of the main pulse.

Meanwhile, the driving voltages VRDC, VWDC1, and VWDC2 are generally output from the R / F unit 40 to the LD driver 50. However, the digital recording signal processor 30a outputs the driving voltage to the LD driver. It is also possible to output to 50, and the driving pulse is output by the digital recording signal processing section 30a to the LD driver 50.

FIG. 6 is a flow chart showing a preferred embodiment of the laser diode driving method for data recording of an optical disc according to the present invention. Hereinafter, the driving method of FIG. 6 according to the present invention in parallel with the operation of the apparatus of FIG. This will be described in detail.

First, in the present invention, as a variable for applying an optimal recording method corresponding to each recording foot for each disc manufacturer, in addition to VRDC, Td and Tf for generating PEO as a main pulse and LDH for generating a subpulse. Ta, Tb, and VWDC1 and VWDC2 are set, wherein Td and Tf represent the magnitude and on and off timing of the main pulse, and Ta and Tb represent the magnitude and on of the subpulse, This signal indicates off timing.

Meanwhile, in the present invention, since VWDC2 is used as the same value as VWDC1, VWDC1 corresponding to each disc manufacturer and each recording foot is detected and stored in the ROM 81, and the Td and Tf are also recorded for each disc manufacturer and each record. Detects a value corresponding to each pit and stores the value in the ROM 81. Since Ta and Tb use the same value for 3T to 1T, which are recording feet for each disc manufacturer, a value corresponding to each disc manufacturer is detected and the ROM It is stored at 81.

Meanwhile, in the present invention, Ta is 50% (duty ratio) detected in the experiment, and Tb is T / 32 (pulse width) detected by the experiment, and Ta and Tb may have different values for each disc manufacturer. Can be.

In this state, when the optical disk (CD-R) 10 is inserted and mounted, the microcomputer 80 determines the manufacturer of the optical disk 10. For example, the microcomputer 80 of the optical disk 10 The start time of the lead-out area is detected from the TOC (Table Of Contents) information recorded in the lead-in area, and the manufacturer of the optical disc 10 is determined therefrom. The lead-out area is a signal indicating the end of the program. Since the start time of the lead-out area is different for each disc manufacturer as an area of, the microcomputer 80 can easily determine the manufacturer of the optical disc 10.

When the manufacturer of the optical disc 10 is determined, the microcomputer 80 detects the variable values of the manufacturer and the respective recorded feet from the ROM 81 in order to apply an optimal recording method (S10). The detected variable values may be adjusted to optimal values according to the characteristics of the optical disk 10 through the OPC operation of the microcomputer 80.

After the recording operation is requested (S20), the microcomputer 80 records the VRDC, VWDC1, and VWDC2 (= VWDC1) among the variable values corresponding to the respective recording feet, and records the R / F unit 40 and digitally. The Td, Tf, Ta, and Tb are respectively applied to the signal processing unit 30a, and the Td, Tf, Ta, and Tb are applied to the digital recording signal processing unit 30a, where Ta is 50% duty ratio and Tb is T / 32.

The digital recording signal processing unit 30a is a PEO (main pulse) which is a driving pulse of the VWDC1 based on the applied Td and Tf, and an LDH (subpulse) which is a driving pulse of the VWDC2 based on the applied Ta and Tb. PWOs, which are driving pulses of the applied VRDC, are respectively generated (S21) and output to the LD driver 50, wherein the digital recording signal processor 30a is applied from the microcomputer 80. Based on the value, the sub pulse is outputted faster than the main pulse for a predetermined time, that is, if the Ta value is 50%, 50% of the width T / 32 of the sub pulse is output faster than the main pulse (S22). do.

In the above description, the signal levels of the main pulse and the sub pulse are the same, and the output PEO, LDH, and PWO are as shown in FIG.

Meanwhile, the R / F unit 40 outputs the applied driving voltages VRDC, VWDC1, and VWDC2 to the LD driver 50. The output VRDC, VWDC1, and VWDC2 are as illustrated in FIG. .

The LD driver 50 applies a driving voltage VRDC applied from the R / F unit 40 through a switching operation by driving pulses PEO, LDH, and PWO applied from the digital recording signal processing unit 30a. , VWDC1, VWDC2), and consequently, the LD driver 50 outputs the LD driving signal of the type shown in FIG. 9 to the LD of the optical pickup 20 (S23), and thus the optical The pickup 20 is an optical power controlled by the LD driving signal, and records data on the optical disc 10 (S24). The recording operation continues until the recording operation is terminated (S30). Is done.

As shown in FIG. 9, the LD driving signal according to the present invention overlaps the rising part of the main pulse and the rising part of the sub pulse, and the rising part may be configured to rise quickly according to the waveform of the sub pulse. .

Fig. 10 shows a comparison between the conventional mode 1 (Orange 1) and mode 2 (Orange 2) recording methods and the recording mode on the optical disc according to the recording method of the present invention, in which the recording mode by the conventional mode 1 recording method is the most stable. However, it can be seen that the recording mode by the recording method according to the present invention also forms recording feet which can be sufficiently reproduced as compared with the conventional mode 2 recording method.

As described above, the present invention does not need to set the sub-drive voltage VWDC2, and since Ta and Tb use the same value for each recording foot, the variable value is detected and stored as compared to the conventional mode 1 recording method. The amount of work and time are small, and even during the recording operation, the sub-pulse enables the formation of recording feet that are similar to the level of the conventional mode 1 recording method and that are more accurate and stable than the conventional mode 2 recording method.

The above-described preferred embodiments of the present invention are disclosed for purposes of illustration, and those skilled in the art can improve, change, and substitute various other embodiments within the technical spirit and scope of the present invention disclosed in the appended claims below. Or addition may be possible.

The laser diode driving apparatus and method for data recording of an optical disc according to the present invention made as described above is optimized by recording data using a drive signal without overpower as in the conventional mode 2 recording method. The amount of work and time required according to the detection and storage of variable values to apply the recording method is small, and when the recording operation is performed, the recording feet of the desired size are accurate and stable at a desired time point as in the conventional mode 1 recording method. It is a very useful invention having the effect of improving the recording quality by being formed.

Claims (10)

In the optical disk device, Optical pickup means for recording data on the optical disc; Optical driving means for outputting an LD driving signal for driving the laser diode (LD) of the optical pickup means to adjust the optical power of the optical pickup means; And And a control means for generating and outputting a main pulse for the drive signal and a sub pulse having a predetermined width, and outputting the sub pulse a predetermined time before the main pulse. The method of claim 1, And said sub-pulse is superimposed with said main pulse for said predetermined time. The method of claim 1, And a signal level of the sub-pulse and a signal level of the main-pulse are the same. The method of claim 1, The optical driving means operates with a signal indicating the magnitude of the main pulse and the on / off timing of the main pulse, and a signal indicating the magnitude of the subpulse and the on / off timing of the subpulse. A laser diode drive for recording data on an optical disc, characterized in that the. The method of claim 1, And storage means for storing variables representing the start, end, and size of the main pulse and the subpulse corresponding to the size of each recording foot, wherein the control means stores the corresponding data according to the size of the recording feet. And a main pulse and a sub-pulse are generated and output as variables in the means. The method of claim 5, Width of the sub-pulse is constant regardless of the size of the recording feet. The method of claim 1, And a storage means for storing variables representing the start, end, and size of the main pulse and the sub-pulse for each disc manufacturer, wherein the control means is a variable in the storage means corresponding to the disc manufacturer. A laser diode drive for recording data on an optical disc, characterized in that for generating and outputting pulses and subpulses. A first step of confirming the manufacturer of the inserted optical disc and the value of the previously detected and stored variable corresponding to each recording fit; A second step of generating and outputting a sub-pulse having a main pulse and a predetermined width based on the identified value, and outputting the sub-pulse a predetermined time before the main pulse; A third step of outputting a driving signal for driving an optical pickup internal laser diode from the main pulse and the subpulse; And And a fourth step of recording data on the optical disc with the optical power regulated by the drive signal. The method of claim 8, And the sub-pulse has the same signal level as the main pulse and a pulse width of less than 1T. The method of claim 8, The variable value checked in the first step may include a variable value indicating the magnitude of the main pulse and the on / off timing of the main pulse, the magnitude of the subpulse and the on / off of the subpulse. A method of driving a laser diode for recording data on an optical disc, comprising: a variable value representing a timing.